/*
 * FreeRTOS V202012.00
 * Copyright (C) 2020 Amazon.com, Inc. or its affiliates.  All Rights Reserved.
 *
 * Permission is hereby granted, free of charge, to any person obtaining a copy of
 * this software and associated documentation files (the "Software"), to deal in
 * the Software without restriction, including without limitation the rights to
 * use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of
 * the Software, and to permit persons to whom the Software is furnished to do so,
 * subject to the following conditions:
 *
 * The above copyright notice and this permission notice shall be included in all
 * copies or substantial portions of the Software.
 *
 * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
 * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS
 * FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR
 * COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER
 * IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN
 * CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
 *
 * http://www.FreeRTOS.org
 * http://aws.amazon.com/freertos
 *
 * 1 tab == 4 spaces!
 */


/*
 * Demonstrates how to create FreeRTOS objects using pre-allocated memory,
 * rather than the normal dynamically allocated memory, and tests objects being
 * created and deleted with both statically allocated memory and dynamically
 * allocated memory.
 *
 * See http://www.FreeRTOS.org/Static_Vs_Dynamic_Memory_Allocation.html
 */

/* Scheduler include files. */
#include "FreeRTOS.h"
#include "task.h"
#include "queue.h"
#include "semphr.h"
#include "event_groups.h"
#include "timers.h"

/* Demo program include files. */
#include "StaticAllocation.h"

/* Exclude the entire file if configSUPPORT_STATIC_ALLOCATION is 0. */
#if( configSUPPORT_STATIC_ALLOCATION == 1 )

/* The priority at which the task that performs the tests is created. */
#define staticTASK_PRIORITY					( tskIDLE_PRIORITY + 2 )

/* The length of the queue, in items, not bytes, used in the queue static
allocation tests. */
#define staticQUEUE_LENGTH_IN_ITEMS			( 5 )

/* A block time of 0 simply means "don't block". */
#define staticDONT_BLOCK					( ( TickType_t ) 0 )

/* Binary semaphores have a maximum count of 1. */
#define staticBINARY_SEMAPHORE_MAX_COUNT	( 1 )

/* The size of the stack used by the task that runs the tests. */
#define staticCREATOR_TASK_STACK_SIZE		( configMINIMAL_STACK_SIZE * 2 )

/* The number of times the software timer will execute before stopping itself. */
#define staticMAX_TIMER_CALLBACK_EXECUTIONS	( 5 )


/*-----------------------------------------------------------*/

/*
 * The task that repeatedly creates and deletes statically allocated tasks, and
 * other RTOS objects.
 */
static void prvStaticallyAllocatedCreator( void *pvParameters );

/*
 * The callback function used by the software timer that is repeatedly created
 * and deleted using both static and dynamically allocated memory.
 */
static void prvTimerCallback( TimerHandle_t xExpiredTimer );

/*
 * A task that is created and deleted multiple times, using both statically and
 * dynamically allocated stack and TCB.
 */
static void prvStaticallyAllocatedTask( void *pvParameters );

/*
 * A function that demonstrates and tests the API functions that create and
 * delete tasks using both statically and dynamically allocated TCBs and stacks.
 */
static void prvCreateAndDeleteStaticallyAllocatedTasks( void );

/*
 * A function that demonstrates and tests the API functions that create and
 * delete event groups using both statically and dynamically allocated RAM.
 */
static void prvCreateAndDeleteStaticallyAllocatedEventGroups( void );

/*
 * A function that demonstrates and tests the API functions that create and
 * delete queues using both statically and dynamically allocated RAM.
 */
static void prvCreateAndDeleteStaticallyAllocatedQueues( void );

/*
 * A function that demonstrates and tests the API functions that create and
 * delete binary semaphores using both statically and dynamically allocated RAM.
 */
static void prvCreateAndDeleteStaticallyAllocatedBinarySemaphores( void );

/*
 * A function that demonstrates and tests the API functions that create and
 * delete software timers using both statically and dynamically allocated RAM.
 */
static void prvCreateAndDeleteStaticallyAllocatedTimers( void );

/*
 * A function that demonstrates and tests the API functions that create and
 * delete mutexes using both statically and dynamically allocated RAM.
 */
static void prvCreateAndDeleteStaticallyAllocatedMutexes( void );

/*
 * A function that demonstrates and tests the API functions that create and
 * delete counting semaphores using both statically and dynamically allocated
 * RAM.
 */
static void prvCreateAndDeleteStaticallyAllocatedCountingSemaphores( void );

/*
 * A function that demonstrates and tests the API functions that create and
 * delete recursive mutexes using both statically and dynamically allocated RAM.
 */
static void prvCreateAndDeleteStaticallyAllocatedRecursiveMutexes( void );

/*
 * Utility function to create pseudo random numbers.
 */
static UBaseType_t prvRand( void );

/*
 * The task that creates and deletes other tasks has to delay occasionally to
 * ensure lower priority tasks are not starved of processing time.  A pseudo
 * random delay time is used just to add a little bit of randomisation into the
 * execution pattern.  prvGetNextDelayTime() generates the pseudo random delay.
 */
static TickType_t prvGetNextDelayTime( void );

/*
 * Checks the basic operation of a queue after it has been created.
 */
static void prvSanityCheckCreatedQueue( QueueHandle_t xQueue );

/*
 * Checks the basic operation of a recursive mutex after it has been created.
 */
static void prvSanityCheckCreatedRecursiveMutex( SemaphoreHandle_t xSemaphore );

/*
 * Checks the basic operation of a binary semaphore after it has been created.
 */
static void prvSanityCheckCreatedSemaphore( SemaphoreHandle_t xSemaphore, UBaseType_t uxMaxCount );

/*
 * Checks the basic operation of an event group after it has been created.
 */
static void prvSanityCheckCreatedEventGroup( EventGroupHandle_t xEventGroup );

/*-----------------------------------------------------------*/

/* StaticTask_t is a publicly accessible structure that has the same size and
alignment requirements as the real TCB structure.  It is provided as a mechanism
for applications to know the size of the TCB (which is dependent on the
architecture and configuration file settings) without breaking the strict data
hiding policy by exposing the real TCB.  This StaticTask_t variable is passed
into the xTaskCreateStatic() function that creates the
prvStaticallyAllocatedCreator() task, and will hold the TCB of the created
tasks. */
static StaticTask_t xCreatorTaskTCBBuffer;

/* This is the stack that will be used by the prvStaticallyAllocatedCreator()
task, which is itself created using statically allocated buffers (so without any
dynamic memory allocation). */
static StackType_t uxCreatorTaskStackBuffer[ staticCREATOR_TASK_STACK_SIZE ];

/* Used by the pseudo random number generating function. */
static uint32_t ulNextRand = 0;

/* Used so a check task can ensure this test is still executing, and not
stalled. */
static volatile UBaseType_t uxCycleCounter = 0;

/* A variable that gets set to pdTRUE if an error is detected. */
static volatile BaseType_t xErrorOccurred = pdFALSE;

/*-----------------------------------------------------------*/

void vStartStaticallyAllocatedTasks( void  )
{
	/* Create a single task, which then repeatedly creates and deletes the other
	RTOS objects using both statically and dynamically allocated RAM. */
	xTaskCreateStatic( prvStaticallyAllocatedCreator,		/* The function that implements the task being created. */
					   "StatCreate",						/* Text name for the task - not used by the RTOS, its just to assist debugging. */
					   staticCREATOR_TASK_STACK_SIZE,		/* Size of the buffer passed in as the stack - in words, not bytes! */
					   NULL,								/* Parameter passed into the task - not used in this case. */
					   staticTASK_PRIORITY,					/* Priority of the task. */
					   &( uxCreatorTaskStackBuffer[ 0 ] ),  /* The buffer to use as the task's stack. */
					   &xCreatorTaskTCBBuffer );			/* The variable that will hold the task's TCB. */
}
/*-----------------------------------------------------------*/

static void prvStaticallyAllocatedCreator( void *pvParameters )
{
	/* Avoid compiler warnings. */
	( void ) pvParameters;

	for( ;; )
	{
		/* Loop, running functions that create and delete the various RTOS
		objects that can be optionally created using either static or dynamic
		memory allocation. */
		prvCreateAndDeleteStaticallyAllocatedTasks();
		prvCreateAndDeleteStaticallyAllocatedQueues();

		/* Delay to ensure lower priority tasks get CPU time, and increment the
		cycle counter so a 'check' task can determine that this task is still
		executing. */
		vTaskDelay( prvGetNextDelayTime() );
		uxCycleCounter++;

		prvCreateAndDeleteStaticallyAllocatedBinarySemaphores();
		prvCreateAndDeleteStaticallyAllocatedCountingSemaphores();

		vTaskDelay( prvGetNextDelayTime() );
		uxCycleCounter++;

		prvCreateAndDeleteStaticallyAllocatedMutexes();
		prvCreateAndDeleteStaticallyAllocatedRecursiveMutexes();

		vTaskDelay( prvGetNextDelayTime() );
		uxCycleCounter++;

		prvCreateAndDeleteStaticallyAllocatedEventGroups();
		prvCreateAndDeleteStaticallyAllocatedTimers();
	}
}
/*-----------------------------------------------------------*/

static void prvCreateAndDeleteStaticallyAllocatedCountingSemaphores( void )
{
SemaphoreHandle_t xSemaphore;
const UBaseType_t uxMaxCount = ( UBaseType_t ) 10;

/* StaticSemaphore_t is a publicly accessible structure that has the same size
and alignment requirements as the real semaphore structure.  It is provided as a
mechanism for applications to know the size of the semaphore (which is dependent
on the architecture and configuration file settings) without breaking the strict
data hiding policy by exposing the real semaphore internals.  This
StaticSemaphore_t variable is passed into the xSemaphoreCreateCountingStatic()
function calls within this function.  NOTE: In most usage scenarios now it is
faster and more memory efficient to use a direct to task notification instead of
a counting semaphore.  http://www.freertos.org/RTOS-task-notifications.html */
StaticSemaphore_t xSemaphoreBuffer;

	/* Create the semaphore.  xSemaphoreCreateCountingStatic() has one more
	parameter than the usual xSemaphoreCreateCounting() function.  The parameter
	is a pointer to the pre-allocated StaticSemaphore_t structure, which will
	hold information on the semaphore in an anonymous way.  If the pointer is
	passed as NULL then the structure will be allocated dynamically, just as
	when xSemaphoreCreateCounting() is called. */
	xSemaphore = xSemaphoreCreateCountingStatic( uxMaxCount, 0, &xSemaphoreBuffer );

	/* The semaphore handle should equal the static semaphore structure passed
	into the xSemaphoreCreateBinaryStatic() function. */
	configASSERT( xSemaphore == ( SemaphoreHandle_t ) &xSemaphoreBuffer );

	/* Ensure the semaphore passes a few sanity checks as a valid semaphore. */
	prvSanityCheckCreatedSemaphore( xSemaphore, uxMaxCount );

	/* Delete the semaphore again so the buffers can be reused. */
	vSemaphoreDelete( xSemaphore );

	#if( configSUPPORT_DYNAMIC_ALLOCATION == 1 )
	{
		/* Now do the same but using dynamically allocated buffers to ensure the
		delete functions are working correctly in both the static and dynamic
		allocation cases. */
		xSemaphore = xSemaphoreCreateCounting( uxMaxCount, 0 );
		configASSERT( xSemaphore != NULL );
		prvSanityCheckCreatedSemaphore( xSemaphore, uxMaxCount );
		vSemaphoreDelete( xSemaphore );
	}
	#endif
}
/*-----------------------------------------------------------*/

static void prvCreateAndDeleteStaticallyAllocatedRecursiveMutexes( void )
{
SemaphoreHandle_t xSemaphore;

/* StaticSemaphore_t is a publicly accessible structure that has the same size
and alignment requirements as the real semaphore structure.  It is provided as a
mechanism for applications to know the size of the semaphore (which is dependent
on the architecture and configuration file settings) without breaking the strict
data hiding policy by exposing the real semaphore internals.  This
StaticSemaphore_t variable is passed into the
xSemaphoreCreateRecursiveMutexStatic() function calls within this function. */
StaticSemaphore_t xSemaphoreBuffer;

	/* Create the semaphore.  xSemaphoreCreateRecursiveMutexStatic() has one
	more parameter than the usual xSemaphoreCreateRecursiveMutex() function.
	The parameter is a pointer to the pre-allocated StaticSemaphore_t structure,
	which will hold information on the semaphore in an anonymous way.  If the
	pointer is passed as NULL then the structure will be allocated dynamically,
	just as	when xSemaphoreCreateRecursiveMutex() is called. */
	xSemaphore = xSemaphoreCreateRecursiveMutexStatic( &xSemaphoreBuffer );

	/* The semaphore handle should equal the static semaphore structure passed
	into the xSemaphoreCreateBinaryStatic() function. */
	configASSERT( xSemaphore == ( SemaphoreHandle_t ) &xSemaphoreBuffer );

	/* Ensure the semaphore passes a few sanity checks as a valid
	recursive semaphore. */
	prvSanityCheckCreatedRecursiveMutex( xSemaphore );

	/* Delete the semaphore again so the buffers can be reused. */
	vSemaphoreDelete( xSemaphore );

	/* Now do the same using dynamically allocated buffers to ensure the delete
	functions are working correctly in both the static and dynamic memory
	allocation cases. */
	#if( configSUPPORT_DYNAMIC_ALLOCATION == 1 )
	{
		xSemaphore = xSemaphoreCreateRecursiveMutex();
		configASSERT( xSemaphore != NULL );
		prvSanityCheckCreatedRecursiveMutex( xSemaphore );
		vSemaphoreDelete( xSemaphore );
	}
	#endif
}
/*-----------------------------------------------------------*/

static void prvCreateAndDeleteStaticallyAllocatedQueues( void )
{
QueueHandle_t xQueue;

/* StaticQueue_t is a publicly accessible structure that has the same size and
alignment requirements as the real queue structure.  It is provided as a
mechanism for applications to know the size of the queue (which is dependent on
the architecture and configuration file settings) without breaking the strict
data hiding policy by exposing the real queue internals.  This StaticQueue_t
variable is passed into the xQueueCreateStatic() function calls within this
function. */
static StaticQueue_t xStaticQueue;

/* The queue storage area must be large enough to hold the maximum number of
items it is possible for the queue to hold at any one time, which equals the
queue length (in items, not bytes) multiplied by the size of each item.  In this
case the queue will hold staticQUEUE_LENGTH_IN_ITEMS 64-bit items.  See
http://www.freertos.org/Embedded-RTOS-Queues.html */
static uint8_t ucQueueStorageArea[ staticQUEUE_LENGTH_IN_ITEMS * sizeof( uint64_t ) ];

	/* Create the queue.  xQueueCreateStatic() has two more parameters than the
	usual xQueueCreate() function.  The first new parameter is a pointer to the
	pre-allocated queue storage area.  The second new parameter is a pointer to
	the StaticQueue_t structure that will hold the queue state information in
	an anonymous way.  If the two pointers are passed as NULL then the data
	will be allocated dynamically as if xQueueCreate() had been called. */
	xQueue = xQueueCreateStatic( staticQUEUE_LENGTH_IN_ITEMS, /* The maximum number of items the queue can hold. */
								 sizeof( uint64_t ), /* The size of each item. */
								 ucQueueStorageArea, /* The buffer used to hold items within the queue. */
								 &xStaticQueue );	 /* The static queue structure that will hold the state of the queue. */

	/* The queue handle should equal the static queue structure passed into the
	xQueueCreateStatic() function. */
	configASSERT( xQueue == ( QueueHandle_t ) &xStaticQueue );

	/* Ensure the queue passes a few sanity checks as a valid queue. */
	prvSanityCheckCreatedQueue( xQueue );

	/* Delete the queue again so the buffers can be reused. */
	vQueueDelete( xQueue );

	/* Now do the same using a dynamically allocated queue to ensure the delete
	function is working correctly in both the static and dynamic memory
	allocation cases. */
	#if( configSUPPORT_DYNAMIC_ALLOCATION == 1 )
	{
		xQueue = xQueueCreate( staticQUEUE_LENGTH_IN_ITEMS, /* The maximum number of items the queue can hold. */
							   sizeof( uint64_t ) ); 		/* The size of each item. */

		/* The queue handle should equal the static queue structure passed into the
		xQueueCreateStatic() function. */
		configASSERT( xQueue != NULL );

		/* Ensure the queue passes a few sanity checks as a valid queue. */
		prvSanityCheckCreatedQueue( xQueue );

		/* Delete the queue again so the buffers can be reused. */
		vQueueDelete( xQueue );
	}
	#endif
}
/*-----------------------------------------------------------*/

static void prvCreateAndDeleteStaticallyAllocatedMutexes( void )
{
SemaphoreHandle_t xSemaphore;
BaseType_t xReturned;

/* StaticSemaphore_t is a publicly accessible structure that has the same size
and alignment requirements as the real semaphore structure.  It is provided as a
mechanism for applications to know the size of the semaphore (which is dependent
on the architecture and configuration file settings) without breaking the strict
data hiding policy by exposing the real semaphore internals.  This
StaticSemaphore_t variable is passed into the xSemaphoreCreateMutexStatic()
function calls within this function. */
StaticSemaphore_t xSemaphoreBuffer;

	/* Create the semaphore.  xSemaphoreCreateMutexStatic() has one more
	parameter than the usual xSemaphoreCreateMutex() function.  The parameter
	is a pointer to the pre-allocated StaticSemaphore_t structure, which will
	hold information on the semaphore in an anonymous way.  If the pointer is
	passed as NULL then the structure will be allocated dynamically, just as
	when xSemaphoreCreateMutex() is called. */
	xSemaphore = xSemaphoreCreateMutexStatic( &xSemaphoreBuffer );

	/* The semaphore handle should equal the static semaphore structure passed
	into the xSemaphoreCreateMutexStatic() function. */
	configASSERT( xSemaphore == ( SemaphoreHandle_t ) &xSemaphoreBuffer );

	/* Take the mutex so the mutex is in the state expected by the
	prvSanityCheckCreatedSemaphore() function. */
	xReturned = xSemaphoreTake( xSemaphore, staticDONT_BLOCK );

	if( xReturned != pdPASS )
	{
		xErrorOccurred = pdTRUE;
	}

	/* Ensure the semaphore passes a few sanity checks as a valid semaphore. */
	prvSanityCheckCreatedSemaphore( xSemaphore, staticBINARY_SEMAPHORE_MAX_COUNT );

	/* Delete the semaphore again so the buffers can be reused. */
	vSemaphoreDelete( xSemaphore );

	/* Now do the same using a dynamically allocated mutex to ensure the delete
	function is working correctly in both the static and dynamic allocation
	cases. */
	#if( configSUPPORT_DYNAMIC_ALLOCATION == 1 )
	{
		xSemaphore = xSemaphoreCreateMutex();

		/* The semaphore handle should equal the static semaphore structure
		passed into the xSemaphoreCreateMutexStatic() function. */
		configASSERT( xSemaphore != NULL );

		/* Take the mutex so the mutex is in the state expected by the
		prvSanityCheckCreatedSemaphore() function. */
		xReturned = xSemaphoreTake( xSemaphore, staticDONT_BLOCK );

		if( xReturned != pdPASS )
		{
			xErrorOccurred = pdTRUE;
		}

		/* Ensure the semaphore passes a few sanity checks as a valid semaphore. */
		prvSanityCheckCreatedSemaphore( xSemaphore, staticBINARY_SEMAPHORE_MAX_COUNT );

		/* Delete the semaphore again so the buffers can be reused. */
		vSemaphoreDelete( xSemaphore );
	}
	#endif
}
/*-----------------------------------------------------------*/

static void prvCreateAndDeleteStaticallyAllocatedBinarySemaphores( void )
{
SemaphoreHandle_t xSemaphore;

/* StaticSemaphore_t is a publicly accessible structure that has the same size
and alignment requirements as the real semaphore structure.  It is provided as a
mechanism for applications to know the size of the semaphore (which is dependent
on the architecture and configuration file settings) without breaking the strict
data hiding policy by exposing the real semaphore internals.  This
StaticSemaphore_t variable is passed into the xSemaphoreCreateBinaryStatic()
function calls within this function.  NOTE: In most usage scenarios now it is
faster and more memory efficient to use a direct to task notification instead of
a binary semaphore.  http://www.freertos.org/RTOS-task-notifications.html */
StaticSemaphore_t xSemaphoreBuffer;

	/* Create the semaphore.  xSemaphoreCreateBinaryStatic() has one more
	parameter than the usual xSemaphoreCreateBinary() function.  The parameter
	is a pointer to the pre-allocated StaticSemaphore_t structure, which will
	hold information on the semaphore in an anonymous way.  If the pointer is
	passed as NULL then the structure will be allocated dynamically, just as
	when xSemaphoreCreateBinary() is called. */
	xSemaphore = xSemaphoreCreateBinaryStatic( &xSemaphoreBuffer );

	/* The semaphore handle should equal the static semaphore structure passed
	into the xSemaphoreCreateBinaryStatic() function. */
	configASSERT( xSemaphore == ( SemaphoreHandle_t ) &xSemaphoreBuffer );

	/* Ensure the semaphore passes a few sanity checks as a valid semaphore. */
	prvSanityCheckCreatedSemaphore( xSemaphore, staticBINARY_SEMAPHORE_MAX_COUNT );

	/* Delete the semaphore again so the buffers can be reused. */
	vSemaphoreDelete( xSemaphore );

	/* Now do the same using a dynamically allocated semaphore to check the
	delete function is working correctly in both the static and dynamic
	allocation cases. */
	#if( configSUPPORT_DYNAMIC_ALLOCATION == 1 )
	{
		xSemaphore = xSemaphoreCreateBinary();
		configASSERT( xSemaphore != NULL );
		prvSanityCheckCreatedSemaphore( xSemaphore, staticBINARY_SEMAPHORE_MAX_COUNT );
		vSemaphoreDelete( xSemaphore );
	}
	#endif

	/* There isn't a static version of the old and deprecated
	vSemaphoreCreateBinary() macro (because its deprecated!), but check it is
	still functioning correctly. */
	#if( configSUPPORT_DYNAMIC_ALLOCATION == 1 )
	{
		vSemaphoreCreateBinary( xSemaphore );

		/* The macro starts with the binary semaphore available, but the test
		function expects it to be unavailable. */
		if( xSemaphoreTake( xSemaphore, staticDONT_BLOCK ) == pdFAIL )
		{
			xErrorOccurred = pdTRUE;
		}

		prvSanityCheckCreatedSemaphore( xSemaphore, staticBINARY_SEMAPHORE_MAX_COUNT );
		vSemaphoreDelete( xSemaphore );
	}
	#endif
}
/*-----------------------------------------------------------*/

static void prvTimerCallback( TimerHandle_t xExpiredTimer )
{
UBaseType_t *puxVariableToIncrement;
BaseType_t xReturned;

	/* The timer callback just demonstrates it is executing by incrementing a
	variable - the address of which is passed into the timer as its ID.  Obtain
	the address of the variable to increment. */
	puxVariableToIncrement = ( UBaseType_t * ) pvTimerGetTimerID( xExpiredTimer );

	/* Increment the variable to show the timer callback has executed. */
	( *puxVariableToIncrement )++;

	/* If this callback has executed the required number of times, stop the
	timer. */
	if( *puxVariableToIncrement == staticMAX_TIMER_CALLBACK_EXECUTIONS )
	{
		/* This is called from a timer callback so must not block.  See
		http://www.FreeRTOS.org/FreeRTOS-timers-xTimerStop.html */
		xReturned = xTimerStop( xExpiredTimer, staticDONT_BLOCK );

		if( xReturned != pdPASS )
		{
			xErrorOccurred = pdTRUE;
		}
	}
}
/*-----------------------------------------------------------*/

static void prvCreateAndDeleteStaticallyAllocatedTimers( void )
{
TimerHandle_t xTimer;
UBaseType_t uxVariableToIncrement;
const TickType_t xTimerPeriod = pdMS_TO_TICKS( 20 );
BaseType_t xReturned;

/* StaticTimer_t is a publicly accessible structure that has the same size
and alignment requirements as the real timer structure.  It is provided as a
mechanism for applications to know the size of the timer structure (which is
dependent on the architecture and configuration file settings) without breaking
the strict data hiding policy by exposing the real timer internals.  This
StaticTimer_t variable is passed into the xTimerCreateStatic() function calls
within this function. */
StaticTimer_t xTimerBuffer;

	/* Create the software time.  xTimerCreateStatic() has an extra parameter
	than the normal xTimerCreate() API function.  The parameter is a pointer to
	the StaticTimer_t structure that will hold the software timer structure.  If
	the parameter is passed as NULL then the structure will be allocated
	dynamically, just as if xTimerCreate() had been called. */
	xTimer = xTimerCreateStatic( "T1",					/* Text name for the task.  Helps debugging only.  Not used by FreeRTOS. */
								 xTimerPeriod,			/* The period of the timer in ticks. */
								 pdTRUE,				/* This is an auto-reload timer. */
								 ( void * ) &uxVariableToIncrement,	/* The variable incremented by the test is passed into the timer callback using the timer ID. */
								 prvTimerCallback,		/* The function to execute when the timer expires. */
								 &xTimerBuffer );		/* The buffer that will hold the software timer structure. */

	/* The timer handle should equal the static timer structure passed into the
	xTimerCreateStatic() function. */
	configASSERT( xTimer == ( TimerHandle_t ) &xTimerBuffer );

	/* Set the variable to 0, wait for a few timer periods to expire, then check
	the timer callback has incremented the variable to the expected value. */
	uxVariableToIncrement = 0;

	/* This is a low priority so a block time should not be needed. */
	xReturned = xTimerStart( xTimer, staticDONT_BLOCK );

	if( xReturned != pdPASS )
	{
		xErrorOccurred = pdTRUE;
	}

	vTaskDelay( xTimerPeriod * staticMAX_TIMER_CALLBACK_EXECUTIONS );

	/* By now the timer should have expired staticMAX_TIMER_CALLBACK_EXECUTIONS
	times, and then stopped itself. */
	if( uxVariableToIncrement != staticMAX_TIMER_CALLBACK_EXECUTIONS )
	{
		xErrorOccurred = pdTRUE;
	}

	/* Finished with the timer, delete it. */
	xReturned = xTimerDelete( xTimer, staticDONT_BLOCK );

	/* Again, as this is a low priority task it is expected that the timer
	command will have been sent even without a block time being used. */
	if( xReturned != pdPASS )
	{
		xErrorOccurred = pdTRUE;
	}

	/* Just to show the check task that this task is still executing. */
	uxCycleCounter++;

	/* Now do the same using a dynamically allocated software timer to ensure
	the delete function is working correctly in both the static and dynamic
	allocation cases. */
	#if( configSUPPORT_DYNAMIC_ALLOCATION == 1 )
	{
		xTimer = xTimerCreate( "T1",								/* Text name for the task.  Helps debugging only.  Not used by FreeRTOS. */
							    xTimerPeriod,						/* The period of the timer in ticks. */
								pdTRUE,								/* This is an auto-reload timer. */
								( void * ) &uxVariableToIncrement,	/* The variable incremented by the test is passed into the timer callback using the timer ID. */
								prvTimerCallback );					/* The function to execute when the timer expires. */

		configASSERT( xTimer != NULL );

		uxVariableToIncrement = 0;
		xReturned = xTimerStart( xTimer, staticDONT_BLOCK );

		if( xReturned != pdPASS )
		{
			xErrorOccurred = pdTRUE;
		}

		vTaskDelay( xTimerPeriod * staticMAX_TIMER_CALLBACK_EXECUTIONS );

		if( uxVariableToIncrement != staticMAX_TIMER_CALLBACK_EXECUTIONS )
		{
			xErrorOccurred = pdTRUE;
		}

		xReturned = xTimerDelete( xTimer, staticDONT_BLOCK );

		if( xReturned != pdPASS )
		{
			xErrorOccurred = pdTRUE;
		}
	}
	#endif
}
/*-----------------------------------------------------------*/

static void prvCreateAndDeleteStaticallyAllocatedEventGroups( void )
{
EventGroupHandle_t xEventGroup;

/* StaticEventGroup_t is a publicly accessible structure that has the same size
and alignment requirements as the real event group structure.  It is provided as
a mechanism for applications to know the size of the event group (which is
dependent on the architecture and configuration file settings) without breaking
the strict data hiding policy by exposing the real event group internals.  This
StaticEventGroup_t variable is passed into the xSemaphoreCreateEventGroupStatic()
function calls within this function. */
StaticEventGroup_t xEventGroupBuffer;

	/* Create the event group.  xEventGroupCreateStatic() has an extra parameter
	than the normal xEventGroupCreate() API function.  The parameter is a
	pointer to the StaticEventGroup_t structure that will hold the event group
	structure. */
	xEventGroup = xEventGroupCreateStatic( &xEventGroupBuffer );

	/* The event group handle should equal the static event group structure
	passed into the xEventGroupCreateStatic() function. */
	configASSERT( xEventGroup == ( EventGroupHandle_t ) &xEventGroupBuffer );

	/* Ensure the event group passes a few sanity checks as a valid event
	group. */
	prvSanityCheckCreatedEventGroup( xEventGroup );

	/* Delete the event group again so the buffers can be reused. */
	vEventGroupDelete( xEventGroup );

	/* Now do the same using a dynamically allocated event group to ensure the
	delete function is working correctly in both the static and dynamic
	allocation cases. */
	#if( configSUPPORT_DYNAMIC_ALLOCATION == 1 )
	{
		xEventGroup = xEventGroupCreate();
		configASSERT( xEventGroup != NULL );
		prvSanityCheckCreatedEventGroup( xEventGroup );
		vEventGroupDelete( xEventGroup );
	}
	#endif
}
/*-----------------------------------------------------------*/

static void prvCreateAndDeleteStaticallyAllocatedTasks( void )
{
TaskHandle_t xCreatedTask;

/* The variable that will hold the TCB of tasks created by this function.  See
the comments above the declaration of the xCreatorTaskTCBBuffer variable for
more information.  NOTE:  This is not static so relies on the tasks that use it
being deleted before this function returns and deallocates its stack.  That will
only be the case if configUSE_PREEMPTION is set to 1. */
StaticTask_t xTCBBuffer;

/* This buffer that will be used as the stack of tasks created by this function.
See the comments above the declaration of the uxCreatorTaskStackBuffer[] array
above for more information. */
static StackType_t uxStackBuffer[ configMINIMAL_STACK_SIZE ];

	/* Create the task.  xTaskCreateStatic() has two more parameters than
	the usual xTaskCreate() function.  The first new parameter is a pointer to
	the pre-allocated stack.  The second new parameter is a pointer to the
	StaticTask_t structure that will hold the task's TCB.  If both pointers are
	passed as NULL then the respective object will be allocated dynamically as
	if xTaskCreate() had been called. */
	xCreatedTask = xTaskCreateStatic(
						prvStaticallyAllocatedTask, 	/* Function that implements the task. */
						"Static",						/* Human readable name for the task. */
						configMINIMAL_STACK_SIZE,		/* Task's stack size, in words (not bytes!). */
						NULL,							/* Parameter to pass into the task. */
						uxTaskPriorityGet( NULL ) + 1,	/* The priority of the task. */
						&( uxStackBuffer[ 0 ] ),		/* The buffer to use as the task's stack. */
						&xTCBBuffer );					/* The variable that will hold that task's TCB. */

	/* Check the task was created correctly, then delete the task. */
	if( xCreatedTask == NULL )
	{
		xErrorOccurred = pdTRUE;
	}
	else if( eTaskGetState( xCreatedTask ) != eSuspended )
	{
		/* The created task had a higher priority so should have executed and
		suspended itself by now. */
		xErrorOccurred = pdTRUE;
	}
	else
	{
		vTaskDelete( xCreatedTask );
	}

	/* Now do the same using a dynamically allocated task to ensure the delete
	function is working correctly in both the static and dynamic allocation
	cases. */
	#if( configSUPPORT_DYNAMIC_ALLOCATION == 1 )
	{
	BaseType_t xReturned;

		xReturned = xTaskCreate(
									prvStaticallyAllocatedTask,		/* Function that implements the task - the same function is used but is actually dynamically allocated this time. */
									"Static",						/* Human readable name for the task. */
									configMINIMAL_STACK_SIZE,		/* Task's stack size, in words (not bytes!). */
									NULL,							/* Parameter to pass into the task. */
									uxTaskPriorityGet( NULL ) + 1,	/* The priority of the task. */
									&xCreatedTask );				/* Handle of the task being created. */

		if( eTaskGetState( xCreatedTask ) != eSuspended )
		{
			xErrorOccurred = pdTRUE;
		}

		configASSERT( xReturned == pdPASS );
		if( xReturned != pdPASS )
		{
			xErrorOccurred = pdTRUE;
		}
		vTaskDelete( xCreatedTask );
	}
	#endif
}
/*-----------------------------------------------------------*/

static void prvStaticallyAllocatedTask( void *pvParameters )
{
	( void ) pvParameters;

	/* The created task just suspends itself to wait to get deleted.  The task
	that creates this task checks this task is in the expected Suspended state
	before deleting it. */
	vTaskSuspend( NULL );
}
/*-----------------------------------------------------------*/

static UBaseType_t prvRand( void )
{
const uint32_t ulMultiplier = 0x015a4e35UL, ulIncrement = 1UL;

	/* Utility function to generate a pseudo random number. */
	ulNextRand = ( ulMultiplier * ulNextRand ) + ulIncrement;
	return( ( ulNextRand >> 16UL ) & 0x7fffUL );
}
/*-----------------------------------------------------------*/

static TickType_t prvGetNextDelayTime( void )
{
TickType_t xNextDelay;
const TickType_t xMaxDelay = pdMS_TO_TICKS( ( TickType_t ) 150 );
const TickType_t xMinDelay = pdMS_TO_TICKS( ( TickType_t ) 75 );
const TickType_t xTinyDelay = pdMS_TO_TICKS( ( TickType_t ) 2 );

	/* Generate the next delay time.  This is kept within a narrow band so as
	not to disturb the timing of other tests - but does add in some pseudo
	randomisation into the tests. */
	do
	{
		xNextDelay = prvRand() % xMaxDelay;

		/* Just in case this loop is executed lots of times. */
		vTaskDelay( xTinyDelay );

	} while ( xNextDelay < xMinDelay );

	return xNextDelay;
}
/*-----------------------------------------------------------*/

static void prvSanityCheckCreatedEventGroup( EventGroupHandle_t xEventGroup )
{
EventBits_t xEventBits;
const EventBits_t xFirstTestBits = ( EventBits_t ) 0xaa, xSecondTestBits = ( EventBits_t ) 0x55;

	/* The event group should not have any bits set yet. */
	xEventBits = xEventGroupGetBits( xEventGroup );

	if( xEventBits != ( EventBits_t ) 0 )
	{
		xErrorOccurred = pdTRUE;
	}

	/* Some some bits, then read them back to check they are as expected. */
	xEventGroupSetBits( xEventGroup, xFirstTestBits );

	xEventBits = xEventGroupGetBits( xEventGroup );

	if( xEventBits != xFirstTestBits )
	{
		xErrorOccurred = pdTRUE;
	}

	xEventGroupSetBits( xEventGroup, xSecondTestBits );

	xEventBits = xEventGroupGetBits( xEventGroup );

	if( xEventBits != ( xFirstTestBits | xSecondTestBits ) )
	{
		xErrorOccurred = pdTRUE;
	}

	/* Finally try clearing some bits too and check that operation proceeds as
	expected. */
	xEventGroupClearBits( xEventGroup, xFirstTestBits );

	xEventBits = xEventGroupGetBits( xEventGroup );

	if( xEventBits != xSecondTestBits )
	{
		xErrorOccurred = pdTRUE;
	}
}
/*-----------------------------------------------------------*/

static void prvSanityCheckCreatedSemaphore( SemaphoreHandle_t xSemaphore, UBaseType_t uxMaxCount )
{
BaseType_t xReturned;
UBaseType_t x;
const TickType_t xShortBlockTime = pdMS_TO_TICKS( 10 );
TickType_t xTickCount;

	/* The binary semaphore should start 'empty', so a call to xSemaphoreTake()
	should fail. */
	xTickCount = xTaskGetTickCount();
	xReturned = xSemaphoreTake( xSemaphore, xShortBlockTime );

	if( ( ( TickType_t ) ( xTaskGetTickCount() - xTickCount ) ) < xShortBlockTime )
	{
		/* Did not block on the semaphore as long as expected. */
		xErrorOccurred = pdTRUE;
	}

	if( xReturned != pdFAIL )
	{
		xErrorOccurred = pdTRUE;
	}

	/* Should be possible to 'give' the semaphore up to a maximum of uxMaxCount
	times. */
	for( x = 0; x < uxMaxCount; x++ )
	{
		xReturned = xSemaphoreGive( xSemaphore );

		if( xReturned == pdFAIL )
		{
			xErrorOccurred = pdTRUE;
		}
	}

	/* Giving the semaphore again should fail, as it is 'full'. */
	xReturned = xSemaphoreGive( xSemaphore );

	if( xReturned != pdFAIL )
	{
		xErrorOccurred = pdTRUE;
	}

	configASSERT( uxSemaphoreGetCount( xSemaphore ) == uxMaxCount );

	/* Should now be possible to 'take' the semaphore up to a maximum of
	uxMaxCount times without blocking. */
	for( x = 0; x < uxMaxCount; x++ )
	{
		xReturned = xSemaphoreTake( xSemaphore, staticDONT_BLOCK );

		if( xReturned == pdFAIL )
		{
			xErrorOccurred = pdTRUE;
		}
	}

	/* Back to the starting condition, where the semaphore should not be
	available. */
	xTickCount = xTaskGetTickCount();
	xReturned = xSemaphoreTake( xSemaphore, xShortBlockTime );

	if( ( ( TickType_t ) ( xTaskGetTickCount() - xTickCount ) ) < xShortBlockTime )
	{
		/* Did not block on the semaphore as long as expected. */
		xErrorOccurred = pdTRUE;
	}

	if( xReturned != pdFAIL )
	{
		xErrorOccurred = pdTRUE;
	}

	configASSERT( uxSemaphoreGetCount( xSemaphore ) == 0 );
}
/*-----------------------------------------------------------*/

static void prvSanityCheckCreatedQueue( QueueHandle_t xQueue )
{
uint64_t ull, ullRead;
BaseType_t xReturned, xLoop;

	/* This test is done twice to ensure the queue storage area wraps. */
	for( xLoop = 0; xLoop < 2; xLoop++ )
	{
		/* A very basic test that the queue can be written to and read from as
		expected.  First the queue should be empty. */
		xReturned = xQueueReceive( xQueue, &ull, staticDONT_BLOCK );
		if( xReturned != errQUEUE_EMPTY )
		{
			xErrorOccurred = pdTRUE;
		}

		/* Now it should be possible to write to the queue staticQUEUE_LENGTH_IN_ITEMS
		times. */
		for( ull = 0; ull < staticQUEUE_LENGTH_IN_ITEMS; ull++ )
		{
			xReturned = xQueueSend( xQueue, &ull, staticDONT_BLOCK );
			if( xReturned != pdPASS )
			{
				xErrorOccurred = pdTRUE;
			}
		}

		/* Should not now be possible to write to the queue again. */
		xReturned = xQueueSend( xQueue, &ull, staticDONT_BLOCK );
		if( xReturned != errQUEUE_FULL )
		{
			xErrorOccurred = pdTRUE;
		}

		/* Now read back from the queue to ensure the data read back matches that
		written. */
		for( ull = 0; ull < staticQUEUE_LENGTH_IN_ITEMS; ull++ )
		{
			xReturned = xQueueReceive( xQueue, &ullRead, staticDONT_BLOCK );

			if( xReturned != pdPASS )
			{
				xErrorOccurred = pdTRUE;
			}

			if( ullRead != ull )
			{
				xErrorOccurred = pdTRUE;
			}
		}

		/* The queue should be empty again. */
		xReturned = xQueueReceive( xQueue, &ull, staticDONT_BLOCK );
		if( xReturned != errQUEUE_EMPTY )
		{
			xErrorOccurred = pdTRUE;
		}
	}
}
/*-----------------------------------------------------------*/

static void prvSanityCheckCreatedRecursiveMutex( SemaphoreHandle_t xSemaphore )
{
const BaseType_t xLoops = 5;
BaseType_t x, xReturned;

	/* A very basic test that the recursive semaphore behaved like a recursive
	semaphore. First the semaphore should not be able to be given, as it has not
	yet been taken. */
	xReturned = xSemaphoreGiveRecursive( xSemaphore );

	if( xReturned != pdFAIL )
	{
		xErrorOccurred = pdTRUE;
	}

	/* Now it should be possible to take the mutex a number of times. */
	for( x = 0; x < xLoops; x++ )
	{
		xReturned = xSemaphoreTakeRecursive( xSemaphore, staticDONT_BLOCK );

		if( xReturned != pdPASS )
		{
			xErrorOccurred = pdTRUE;
		}
	}

	/* Should be possible to give the semaphore the same number of times as it
	was given in the loop above. */
	for( x = 0; x < xLoops; x++ )
	{
		xReturned = xSemaphoreGiveRecursive( xSemaphore );

		if( xReturned != pdPASS )
		{
			xErrorOccurred = pdTRUE;
		}
	}

	/* No more gives should be possible though. */
	xReturned = xSemaphoreGiveRecursive( xSemaphore );

	if( xReturned != pdFAIL )
	{
		xErrorOccurred = pdTRUE;
	}
}
/*-----------------------------------------------------------*/

BaseType_t xAreStaticAllocationTasksStillRunning( void )
{
static UBaseType_t uxLastCycleCounter = 0;
BaseType_t xReturn;

	if( uxCycleCounter == uxLastCycleCounter )
	{
		xErrorOccurred = pdTRUE;
	}
	else
	{
		uxLastCycleCounter = uxCycleCounter;
	}

	if( xErrorOccurred != pdFALSE )
	{
		xReturn = pdFAIL;
	}
	else
	{
		xReturn = pdPASS;
	}

	return xReturn;
}
/*-----------------------------------------------------------*/

/* Exclude the entire file if configSUPPORT_STATIC_ALLOCATION is 0. */
#endif /* configSUPPORT_STATIC_ALLOCATION == 1 */
